Split block decoder for a nonvolatile memory device

ABSTRACT

A non-volatile memory device having a memory array organized into a plurality of memory blocks, having either planar memory cells or stacks of cells. Row decoding circuitry of the memory device is configured to select a group of the plurality of memory blocks in response to a first row address, and to select a memory block of the group for receiving row signals in response to a second row address. Row decoding circuitry associated with each group of memory blocks can have a row pitch spacing that is greater than a row pitch spacing of a single memory block and less than or equal to a total row pitch spacing corresponding to the group of memory blocks.

CROSS REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No.13/836,028, filed Mar. 15, 2013 which claims the benefit of U.S.Provisional Patent Appln No. 61/714,472 filed Oct. 16, 2012, which arehereby incorporated by reference.

FIELD

The present disclosure relates generally to semiconductor memorydevices. More particularly, the present disclosure relates tonon-volatile memory devices.

BACKGROUND

Flash memory is a commonly used type of non-volatile memory inwidespread use as storage for consumer electronics and mass storageapplications. Flash memory is pervasive in popular consumer productssuch as digital audio/video players, cell phones and digital cameras,for storing application data and/or media data. Flash memory can furtherbe used as a dedicated storage device, such as a portable flash drivepluggable into a universal serial port (USB) of a personal computer, anda magnetic hard disk drive (HDD) replacement for example. It is wellknown that flash memory is non-volatile, meaning that it retains storeddata in the absence of power, which provides a power savings advantagefor the above mentioned consumer products. Flash memory is suited forsuch applications due to its relatively high density for a given area ofits memory array.

A commonly used flash memory is NAND flash memory, in which groups offlash memory cells are serially connected with each other in a stringbetween a bitline and a source line, and multiple strings receivingcommon row signals form a memory block. NAND flash memory offers a highbit density per unit area, especially when each cell stores multiplebits of data, thereby reducing the cost per bit for the NAND flashmemory device. As should be well known to those skilled in the art, NANDflash memory arrays are typically formed on a plane of the substrate andthereby extend in a wordline and a bitline direction (ie. X and Y).These are referred to as a planar NAND flash memory array. Other factorsfor reducing the overall cost for a NAND flash memory device is tocontinue scaling down of device feature sizes using the most currentlithography tools for reducing the physical cell size, and to increasethe number of cells per string.

As the limits of semiconductor lithography are approached, new NANDflash memory fabrication methods have evolved to further reduce the costper bit. One method is to increase the cell density by stacking thecells vertically on the semiconductor substrate. While this techniquecertainly increases cell density of a memory array, the reduced rowpitch of each memory block relative to planar NAND flash memory blocksimposes new restrictions to certain circuits surrounding the memoryarray. These circuits are traditionally referred to as pitch-limitedcircuits as their layout is limited by the row pitch of the memoryblocks, which are formed in the x-y plane of the substrate.

SUMMARY

In one aspect, the present disclosure provides a non-volatile memorydevice having a memory array and row decoding circuitry. The memoryarray includes a plurality of memory blocks organized as groups ofmemory blocks. The row decoding circuitry is configured to select agroup of the plurality of memory blocks in response to a first rowaddress and to select a memory block of the group for receiving rowsignals in response to a second row address. According to an embodimentof the present invention, the row decoding circuitry includes firstdecoder logic configured to provide a super block signal correspondingto each group of the plurality of memory blocks in response to the firstrow address, the row signals includes string select signalscorresponding to each memory block of the group, and the non-volatilememory device further includes discharge devices for coupling each ofthe string select signals to ground when the group is unselected. In anaspect of this embodiment, each of the discharge devices is controlledby logic states of the super block signal. In another aspect of thepresent embodiment, the row signals includes ground select signalscorresponding to each memory block of the group, the non-volatile memorydevice further including ground select discharge devices for couplingeach of the ground select signals to ground when the group isunselected. Each of the ground select discharge devices can becontrolled by the logic states of the super block signal. Thenon-volatile memory device can further include high voltage levelshifters for voltage level shifting the super block signals.

In another embodiment of the first aspect, the row decoding circuitryincludes a select logic unit configured to select the group addressed bythe first row address and the memory block of the group addressed by thesecond row address. The first decoder logic and the select logic unitcan be formed on one side of the memory array. The select logic unit isformed within a row pitch of the group, and the first row addressincludes higher order bits of a memory block address. In thisembodiment, the row decoding circuitry includes second decoder logicconfigured to provide block signals corresponding to each memory blockof the group in response to the second row address, where the blocksignals include block select signals corresponding to each memory blockof the group, and row signals for accessing memory cells of each memoryblock of the group. In the current embodiment, the select logic unitincludes a first stage selector configured to pass the row signals to asecond stage selector in response to the super block signal, where thesecond stage selector is configured to selectively pass the row signalsto one memory block of the group corresponding to the super blocksignal, in response to the block select signals. The discharge devicescan be first discharge devices, and the non-volatile memory devicefurther includes second discharge devices, where each of the seconddischarge devices couples a corresponding string select line to groundwhen the corresponding memory block of the group is unselected. Each ofthe second discharge devices can be controlled by logic states of acorresponding block select signal. Furthermore, the row signals caninclude ground select signals corresponding to each memory block of thegroup, and the non-volatile memory device further includes ground selectdischarge devices for coupling each of the ground select signals toground when the corresponding memory block of the group is unselected.Each of the ground select discharge devices can be controlled by thelogic states of the corresponding block select signal.

In the embodiment where the block signals include block select signalscorresponding to each memory block of the group, and row signals foraccessing memory cells of each memory block of the group, the second rowaddress includes a wordline address and lower order bits of the memoryblock address. In this aspect of the embodiment, the second decoderlogic includes a wordline address decoder for providing the row signalsin response to the wordline address, and a block decoder for providingthe block select signals in response to the lower order bits of thememory block address. The second decoder logic can further include awordline driver for driving the row signals received from the wordlineaddress decoder, and high voltage level shifters for voltage levelshifting the block select signals.

In the embodiment where the row decoding circuitry includes seconddecoder logic configured to provide block signals corresponding to eachmemory block of the group in response to the second row address, theblock signals include dedicated sets of row signals corresponding toeach memory block of the group. In an aspect of this embodiment, theselect logic unit includes a selector configured to couple the dedicatedsets of row signals to a corresponding memory block of the group inresponse to the super block signal, and the second decoder logicincludes an address decoder for providing the dedicated sets of rowsignals in response to the second row address, where the second rowaddress includes a wordline address and lower order bits of the memoryblock address. The second decoder logic can include wordline drivers fordriving one of the dedicated sets of row signals with voltage levelsspecific to a memory operation.

Alternately, the second decoder logic includes a wordline driver circuitfor driving master row signals with voltage levels specific to a memoryoperation, a selector circuit for passing the master row signals as oneof the dedicated sets of row signals in response to block selectsignals, and a block decoder for providing the block select signals inresponse to lower order bits of the memory block address. The dischargedevices are first discharge devices, and the non-volatile memory devicefurther includes second discharge devices, where each of the seconddischarge devices couples a corresponding string select line to groundwhen the corresponding memory block of the group is unselected.Furthermore, the row signals can include ground select signalscorresponding to each memory block of the group, and the non-volatilememory device further includes ground select discharge devices forcoupling each of the ground select signals to ground when thecorresponding memory block of the group is unselected.

In the embodiment where the row decoding circuitry includes seconddecoder logic configured to provide block signals corresponding to eachmemory block of the group in response to the second row address, thefirst decoder logic includes a first portion formed on one side of thememory array and a second portion formed on an opposite side of thememory array. The first portion provides a first super block signal forselecting a first group of the memory blocks, and the second portionprovides a second super block signal for selecting a second group of thememory blocks. In this aspect of the embodiment, the row decodingcircuitry includes a first select logic unit formed on the one side ofthe memory array for selecting the first group of the memory blocks inresponse to the first super block signal, and a second select logic unitformed on the opposite side of the memory array for selecting the secondgroup of the memory blocks in response to the second super blocksignals. The first select logic unit is configured to select a memoryblock of the first group in response to the block signals, and thesecond logic unit is configured to select a memory block of the secondgroup in response to the block signals. In one embodiment, the firstselect logic unit is formed within a row pitch of the first group of thememory blocks, and the second logic unit is formed within a row pitch ofthe second group of the memory blocks. Alternately, the first selectlogic unit has a row pitch spacing greater than a row pitch of the firstgroup of the memory blocks, and the second logic unit has a row pitchspacing greater than a row pitch of the second group of the memoryblocks.

Other aspects and features of the present disclosure will becomeapparent to those ordinarily skilled in the art upon review of thefollowing description of specific embodiments in conjunction with theaccompanying figures.

BRIEF DESCRIPTION OF THE DRAWINGS

Embodiments of the present disclosure will now be described, by way ofexample only, with reference to the attached Figures.

FIG. 1 is a block diagram of a flash memory device;

FIG. 2 is a circuit schematic of a NAND flash memory array;

FIG. 3 is a block diagram of example row decoder circuits used in theflash memory device of FIG. 1;

FIG. 4 is a circuit schematic of vertical channel NAND flash memoryblocks;

FIG. 5 is a circuit schematic of a vertically stacked NAND flash memoryblocks;

FIG. 6 is a block diagram of a split block row decoder, according to anembodiment of the present disclosure;

FIG. 7 is an example embodiment of the split block row decoder of FIG.6, according to an embodiment of the present disclosure;

FIG. 8 is an alternate example embodiment of the split block row decoderof FIG. 6, according to an embodiment of the present disclosure;

FIG. 9 is an alternate configuration of the split block row decoder ofFIG. 8, according to an embodiment of the present disclosure; and

FIG. 10 is a block diagram of a split block row decoder, according to analternate embodiment of the present disclosure.

DETAILED DESCRIPTION

Generally, the present disclosure is directed to a non-volatile memorydevice having a memory array organized into a plurality of memory blockshaving either planar NAND cell strings or vertical channel NAND cellstrings. Row decoding circuitry of the memory device is configured toselect a group of the plurality of memory blocks in response to a firstrow address, and to select a memory block of the group for receiving rowsignals in response to a second row address. Row decoding circuitryassociated with each group of memory blocks can have a row pitch spacingthat is greater than a row pitch spacing of a single memory block andless than or equal to a total row pitch spacing corresponding to thegroup of memory blocks.

FIG. 1 is a general block diagram of a flash memory device which canincorporate the embodiments of the present disclosure. Flash memory 2includes well known input and output buffer circuits, such asinput/output (I/O) buffer block 6 and control buffer block 8 forreceiving external control and data input signals and providing dataoutput signals. The control buffer block 8 receiving the controlsignals, such as CE# and WE#, may include other basic logic circuits,for implementing rudimentary functions that may be related to control ofthe data input and buffers for example. Flash memory 2 includes controlcircuit 4, for controlling various high level functions of the flashcircuits such as read, program and erase operations for example, anaddress register 10 for storing address information, a data register 12for storing program data information, a command register 14 for storingcommand data information, high voltage circuits for generating therequired program and erase voltages, and core memory circuits foraccessing the memory array 16. Memory array 16 includes flash memorycells, arranged as NAND cell strings for example. The NAND cell stringsof a column are coupled to a bitline, which is connected to a pagebuffer/sense amplifier circuit 18. Sense amplifier circuit 18 sensesread data from a selected page of memory cells and provides program datato a selected page of memory cells. One page refers to the entirety ofall data that is addressed by the least significant bit of the rowaddress. In the most common embodiments all cells that constitute onepage are connected to the same word line. In some embodiments one pageof memory cells is identical to all the memory cells connected to thesame word line. Driving the wordlines is row drivers/decoders, shown asa row address decoder 20 and row address buffer 22. There can be one ormore stages of decoding, and row address buffer 22 can include blockdecoding logic.

The control circuit 4 includes a command decoder and logic for executinginternal flash operations, such as read, program and erase functions.Those skilled in the art will understand that these operations areexecuted in response to the command data stored in the command register14, sometimes in combination with the address data and program datastored in the respective address register 10 and data register 12,depending on the operation to be executed. The command data, addressdata and program data are issued by a memory controller and latched intothe corresponding registers by flash memory 2. The functions of theshown circuit blocks of flash memory 2 are well known in the art.Persons skilled in the art will understand that flash memory 2 shown inFIG. 1 represents one possible flash memory configuration amongst manypossible configurations. In FIG. 1, memory array 16, sense amplifiercircuit 18, data register 12, row address decoder 20 and row addressbuffer 22 are part of one memory bank.

FIG. 2 depicts an example of memory array 16 of FIG. 1. The exampleillustrated in FIG. 2 has two memory blocks in one memory array. In FIG.2, one NAND cell string is outlined with a dashed box 30, which includesa string select device 32, flash memory cells 34, and a sourcelineselect device 36 connected in series between bitline BL1 and source lineSL. There can be “i” flash memory cells 34 per NAND cell string, where“i” is a non-zero integer value indicating the last wordline of the cellstring. Accordingly, wordlines WL1 to WLi are electrically coupled tocorresponding gates of the flash memory cells 34. A string select line(SSL) and a ground select line (GSL) are electrically coupled to selectdevices 32 and 36 respectively. In the present example, all thetransistors of the NAND cell string 30 are n-channel devices.

A memory block 38 includes all the NAND cell strings having selectdevices and flash memory cells connected to the same wordlines, stringselect line and ground select line. The width of memory block 38 is setby the number of bitlines, which in the case of FIG. 2 is “j” bitlineswhere j is a non-zero integer value. Memory block 40 includes furtherNAND cell strings connected to bitlines BL1 to BLj. A bitline and theNAND cell strings electrically connected to it is referred to as acolumn. The NAND cell strings shown in FIG. 2 are planar NAND cellstrings, meaning that they are formed in the semiconductor substrate ofthe memory device. More specifically, semiconductor substrate surfacehas a plane defined by an x axis and a y axis, then the cells of theplanar NAND cell strings are formed with dimensions extending in the xaxis and the y axis.

FIG. 3 is a block diagram of example row decoder circuits for rowaddress decoder 20 of FIG. 1. The memory array includes memory blocks50, 52 and 54 to 56, where memory block 56 is the last memory block “n”in the memory array, where n is an integer value. Each memory blockincludes NAND cell strings having transistor devices sharing common rowsignals, such as wordline, string selection and ground selection lines,as shown in the detailed circuit schematic of memory blocks 52 and 54.Bitlines extend in a vertical direction and are connected to each of theNAND cell strings. Only bitlines BL1, BL2 and a last bitline BLj areshown in FIG. 3. NAND cell strings arranged in memory blocks are wellknown in the art, and a further discussion of their details is notrequired. The row decoder circuits include a block address decoder 58,high voltage level shifter circuits 60, 62 and 64 to 66, pass circuits70, 72 and 74 to 76, a wordline address decoder 80, and wordline drivers82. While not shown in FIG. 3, wordline drivers 82 receives differentvoltage levels, some of which are greater than the power supply voltageprovided to the semiconductor memory device, for driving the row signalswith. In FIG. 3, pass circuits 72 and 74 are shown with circuit details,where each includes a set of pass devices shown as n-channeltransistors, having gate terminals receiving a respective block selectsignal such as BSL1 and BSL2.

The block address decoder 58 decodes a block address to provide blockaddress signals BA1 to BAn. In the present example, only one blockaddress signal BA1 to BAn is driven to the active voltage level inresponse to any block address during read and program operations. Eachof the high voltage level shifters 60 to 66 receives one block addresssignal BA1 to BAn respectively, and shifts the voltage to a highervoltage range than provided by the circuits of block address decoder 58.The high voltage level shifters 60 to 66 can include charge pumps.Alternately, the high voltage level shifters can be transmitter circuitswhich transmit a high voltage provided from a global charge pump circuit(not shown) external to the row decoding circuitry. Such circuits arewell known in the art. Each of the high voltage level shifters 60 to 66therefore provides a level shifted block select signal BSL1 to BSLn torespective pass circuits 70 to 76. It is noted that only one of BSL1 toBSLn is driven to a high voltage level when the corresponding blockaddress BA1 to BAn is driven to the active logic level by block addressdecoder 58. One of pass block circuits 70 to 76 is enabled when itsrespective block select signal BSL is driven to the high voltage level.The effect and purpose of the high voltage level block select signal isdescribed later.

The wordline address decoder 80 decodes a wordline address to activateone global wordline of a set of global row signals GRS. GRS includesglobal wordlines G_WL[1:i] (G_WL1, G_WL2 to G_WLi), a global stringselect line G_SSL and a global ground select line G_GSL. The active andinactive GRS signals are provided to wordline drivers circuit 82. In thepresent example, memory blocks 50, 52 and 54 to 56 each include a totalof “i” rows. The wordline drivers circuit 82 drives global wordlinesG_WL[1:i] (G_WL1, G_WL2 to G_WLi), the global string select line G_SSLand the global ground select line G_GSL to all the pass circuits 70 to76 in parallel. These signals are driven with the appropriate voltagelevels ranging from VSS to various high voltages depending on theoperation being executed, where the high voltages can be provided bycharge pump circuits (not shown).

During read or program operations, a selected G_WL as determined by thewordline address decoder 80 is driven by the wordline drivers circuit 82to the necessary voltage level to effect read or programming operations,while the remaining unselected wordlines, G_SSL and G_GSL are driven toother voltage levels required by the read or program operations. Inorder to transfer or pass the global row signals G_WL[1:i], G_SSL, andG_GSL to one of memory blocks 50, 52 and 54 to 56, one of correspondingpass circuits 70, 72 and 74 to 76 is enabled by a block select signalBSL driven to a high voltage level. The block select signal BSL can bedriven to a voltage level higher than the maximum voltage level theglobal row signals GRS are driven to, in order to ensure that the fullvoltage level of the global row signals is passed to the selected memoryblock. The selected pass block circuit provides local wordline signalsWL[1:i], a local string select signal SSL and a local ground selectsignal GSL to the NAND cell strings of the memory block. Due to thisneed to drive the block select signals BSL0 to BSLn to a high voltagelevel, the high voltage level shifter circuits 60, 62 and 64 to 66 areplaced between the block address decoder 58 and the block select lines(BSL). Also, because the memory blocks are arranged in rows, thecorresponding pass circuits and high voltage level shifter circuits arealso arranged in rows.

It is noted that for unselected pass block circuits, the SSL line forconnecting the NAND cell string to the bitline is held at VSS by adischarge device 59, shown in FIG. 3 as an n-channel transistor. Eachdischarge device 59 is turned on whenever the corresponding memory blockis unselected, in order to decouple the NAND strings from the bitline.Hence, the discharge device 59 is turned off for a selected memoryblock. There can be different methods for turning on and off dischargedevice 59 under these conditions. In the configuration of FIG. 3, theblock address signals are used to enable and disable the dischargedevices 59 via inverters 61. If the block address signal is driven to anactive high logic level to select a particular memory block, then thecorresponding discharge device 59 is turned off. Otherwise, the blockaddress signal at an inactive low logic level turns on the dischargedevice 59. For the purposes of simplifying the drawing of FIG. 3, onlytwo discharge devices 59 and inverters 61 are shown, but would beincluded for the other SSL lines in the memory array. In otherconfigurations, discharge devices can be provided for discharging theGSL lines under the same conditions as the SSL lines are discharged.

In the example of FIG. 3, the memory blocks consist of planar type NANDcell strings. More specifically, the memory cells are arranged on an X -Y plane of the semiconductor surface, where the X axis corresponds to aword line direction and the Y axis corresponds to a bit line direction.It can be seen in FIG. 3 that the memory block pitch, also referred toas row pitch, is determined mainly by the number of cells per NAND cellstring. Therefore, as the number of cells connected in series in theNAND cell string increases, the block pitch will also increase in size.Because the current trend in NAND flash memory development is toincrease the number of cells per NAND cell string, row circuits such asthe high voltage level shifters and the pass circuits corresponding toeach memory block, can be laid out within the block pitch with ease. Inother words, each high voltage level shifter circuit and correspondingpass circuit are pitch matched to a respective memory block andtherefore avoids unnecessary complexity in the layout of the connectionsbetween the high voltage level shifter circuits, pass circuits and thememory blocks.

FIG. 4 shows example memory blocks consisting of vertical channel NANDflash memory cell strings. This is one example of a vertically stacked3D NAND cell string. In such cell strings, the memory cells are formedin a stacked arrangement such that their channels extend in asubstantially vertical direction from the semiconductor substratesurface. The substrate surface of the memory device is defined by theplane having the X axis and Y axis as shown in FIG. 4, which includesthe memory array region 84 where the NAND flash memory blocks composedof vertical channel NAND cell strings 86 are formed. For ease ofillustration, each memory block 86 composed of vertical channel NANDcell strings has the same elements as the planar type NAND flash memoryblock 52 of FIG. 3, and would thus receive the same row signals shown inFIG. 3. The memory blocks 86 can be seen as planar memory block 52having its bitline end flipped upwards by 90 degrees. Therefore, thememory cell strings of memory blocks 86 extend in the z axis relative tothe x-y plane of the substrate surface.

As shown in FIG. 4, the block pitch between adjacent memory blocks 86 isapproximately the Y-axis spacing of a physical vertical channel NANDflash cell. It is noted that the memory blocks 86 are represented asthin sheets and are not drawn to scale. Because of the reduced blockpitch size, it is no longer possible to maintain pitch matching withcorresponding high voltage level shifter and pass circuits. For example,the high voltage level shifter may include large charge pumps. Forcomparison purposes, the outline 88 represents the area occupied by ahigh voltage level shifter circuit and pass circuit corresponding to onememory block similar to the ones shown in FIG. 3, assuming the physicalsize of a vertical channel NAND cell is similar to that of a planar NANDcell. It is clear from FIG. 4 that pitch matching between each memoryblock and corresponding high voltage level shifter circuit and passcircuit is not possible. As a result, complex layout of the row decodercircuit elements will increase design cost, and result in non-uniformwiring lengths as signal lines associated with each memory block may berouted from circuits positioned at varying distances from the respectivememory block.

While FIG. 4 shows one example of a 3D memory array, FIG. 5 is a circuitschematic of another type of 3D memory array. FIG. 5 shows verticallystacked NAND flash memory blocks with horizontal alignment of NAND cellstrings. More specifically, a group of memory blocks 92 are formed insheets 90, shown as x-y planes. Each memory block 92 consists of typeNAND cell strings arranged similarly to those shown in FIG. 3. Eachsheet 90 is stacked on top of other in the z axis direction.

According to an embodiment of the present disclosure, a split blockdecoding scheme is used to hierarchically select a memory block of thememory array to access for read, program or erase operations, whichallows for a simplified layout of row decoding circuits that maintainsconsistent signal line lengths for each memory block. FIG. 6 is a blockdiagram of a split block row decoder according to an embodiment of thepresent disclosure. The split block row decoder includes first decodinglogic 100, second decoding logic 102, and a select block 104. The memoryarray includes super blocks 110 and 112 to 114, where the first superblock is shown as Super Block 0 and the last superblock is shown asSuper Block p, where p is an integer value greater than 0. As shown insuper block 112, each super block includes memory blocks 116, where afirst memory block of a super block is shown as Block 0 and the lastmemory block of a super block is shown as Block r, where r is an integervalue greater than 0. While not shown in FIG. 6, bitlines extending in avertical direction are connected to the NAND cell strings of everymemory block 116 of all the super blocks. The memory blocks 116 caninclude a plurality of planar type NAND cells such as those shown inFIG. 3, or vertically stacked cells such as the vertical channel NANDcells of FIG. 4 or the vertically stacked NAND flash memory blocks withhorizontal alignment of NAND cell strings of FIG. 5.

It is first assumed that the memory device receives a row address, whichis divided into a first row address RA_A and a second row address RA_B.The first decoding logic 100 decodes a first row address RA_A to providesuper block signals SB0 and SB1 to SBp. The first row address RA_A canbe a number of higher order bits of the row address provided to thememory device. Therefore in operation, one of the super block signals isdriven to the active logic level in response to RA_A. The seconddecoding logic 102 decodes a second row address RA_B to provide blocksignals BS for accessing one specific memory block of a selected superblock. The second row address RA_B can be a number of lower order bitsof the row address provided to the memory device. According to oneembodiment, the block signals BS can include block select signals, androw signals received by the NAND cell strings of the selected memoryblock.

The select block 104 receives the super block signals SB0 and SB1 to SBpand the block signals BS for selecting one super block and one memoryblock of the selected super block. In the present embodiments, a memoryblock is selected when its NAND cell strings receives the row signalsdriven to voltage levels necessary for any specific operation, such asread and program operations. In the presently shown embodiment of FIG.6, the select block 104 includes select logic units 120 and 122 to 124,where each select logic unit can provide local row signals RS to onesuper block. By example, select logic unit 120 corresponds to superblock 110, and provides local row signals only to super block 110. Eachselect logic unit selects a respective super block in response to thereceived super block signal, such as SB0 for select logic unit 120, andprovides local row signals RS to a specific memory block of the selectedsuper block in response to the block signals BS. It is noted that theblock signals BS are received in parallel by all the select logic units120 and 122 to 124. Therefore, only the select logic unit receiving anactive logic level super block signal SB provides local row signals RSto the specific memory block of the selected super block. By example, ifSB1 is active in response to RA_A, then select logic unit 122 isenabled. In response to the block signals BS, the select logic unit 122provides row signals of the block select signal to a specific memoryblock 116 of super block 112. In the present embodiment, the local rowsignals RS are provided in the set of block signals BS, which canfurther include specific memory block addressing information.

In the embodiment of FIG. 6, the row circuits, such as the select logicunits 120 and 122 to 124, can be formed within the row pitch of eachrespective super block 110 and 112 to 114. This is advantageous if thememory blocks 116 are formed with vertical channel NAND cell stringshaving a row pitch approximately the spacing of a single physical cell.The second decoding logic 102 circuits can be formed in an area of thechip that is not constrained by the row pitch of any super block ormemory block. This area between the super blocks and the first decodinglogic 100 can be referred to as a row pitch limited area. Therefore,only the row circuits driving signals where signal line length should beminimized remain within the row pitch of a corresponding super block.

FIG. 7 shows an example of the split block decoding scheme embodiment ofFIG. 6. In order to simplify the schematic, the memory array is shown bya first super block 200 and a last super block 202, and each of thesuper blocks includes a first memory block 204 and a second memory block206. Bitlines BL1, BL2 and a last bitline BLj are shown connected to theNAND cell strings of the memory blocks 204 and 206 of all the superblocks. The memory blocks 204 and 206 can include a plurality of planartype NAND cells such as those shown in FIG. 3, or vertically stackedcells such as the vertical channel NAND cells of FIG. 4 or thevertically stacked vertically stacked NAND flash memory blocks withhorizontal alignment of NAND cell strings of FIG. 5. FIG. 7 showsexample electrical connections between the split block decoding circuitsand the super blocks and memory blocks, and does not restrict theembodiment to the specifically shown physical layout or spatialgeometry. The split block decoder of FIG. 7 includes the same firstdecoding logic 100 of FIG. 6, and receives super block addressinformation via first row address RA_A to provide super block signalsSB0 to SBp. The second decoding logic 102 is shown to include a wordlineaddress decoder 210, a block decoder 212, wordline drivers 214 and highvoltage level shifters 216 and 218.

The wordline address decoder 210 receives wordline address informationto provide row signals driven by wordline drivers 214 as global rowsignals GRS, which include global word lines, a string select line and aground select line. The wordline address decoder 210 and the wordlinedrivers 214 can be configured in the same way as wordline addressdecoder 80 and wordline drivers 82 of FIG. 3. The block decoder 212receives block address information to provide block select signals thatare shifted to a high voltage level by high voltage level shifters 216and 218. It is assumed in this example that each super block 200 and 202includes two memory blocks, to better facilitate an understanding of thepresent disclosure. Accordingly, the high voltage level shifters 216 and218 provide global block select signals BSL1 and BSL2. Both the wordlineaddress information and block address information are provided in thesecond row address RA_B. It is noted that the super block address andblock address information are parsed from the received memory blockaddress portion of the row address received by the memory device. Theglobal row signals GRS and global block select signals BSL1 and BSL2 arecollectively referred to as block signals, denoted as BS in FIG. 6.

As only the first super block 204 and the last super block 206 areshown, only the first select logic unit 120 and the last select logicunit 124 corresponding to the first and last super blocks 204 and 206respectively, are shown in FIG. 7. Both select logic units 120 and 124each include a high voltage level shifter 220 and a pass circuit 222.The high voltage level shifters 220 have the same function as highvoltage level shifters 60 to 66 of FIG. 3, and provide level shiftedsuper block signals SB0 to SBp as super block select signals SBSL0 toSBSLp respectively. Example circuit details of the pass circuit 222 areshown in FIG. 7. Each pass circuit 222 includes a first stage selector224 and second stage selector 226, each consisting of pass devices shownas n-channel transistors in the presently shown example. The first stageselectors 224 of all pass circuits 222 receives the global row signalsGRS in parallel. Each first stage selector 224 selectively connects theglobal row signals GRS to a respective second stage selector 226. Eachsecond stage selector 222 selectively connects the global row signalsGRS received from the first stage selector 224 to one memory block.First stage selector 224 of select logic unit 120 is enabled by SBS0,while first stage selector 224 of select logic unit 124 is enabled bySBSLp. The second stage selectors 226 of all the select logic units 120to 124 receive global block select signals BSL1 and BSL2 in parallel.

Because there are two memory blocks 204 and 206 per super block in theexample embodiment of FIG. 7, the second stage selectors 226 of selectlogic units 120 to 124 include two sub-sets of selectors. Each of thesub-sets of selectors selectively passes the global row signals GRSreceived from a first stage selector 224 to one of memory blocks 204 and206 in response to either BSL1 or BSL2. As shown in the example of FIG.7, one sub-set of selectors of second stage selectors 226 comprise passdevices shown as n-channel transistors having gate terminals connectedto BSL1, and another sub-set of selectors comprise similar pass deviceshaving gate terminals connected to BSL2. This connection configurationis repeated for all the pass circuits 222.

Therefore, through the combination of first decoding logic 100 and blockdecoder 212 of second decoding logic 102, one memory block out of themultitude of memory blocks which constitute the cell array is selected.More specifically, the first decoding logic 100 controls the first stageselectors 224, through which one super block out of the multitude ofsuper blocks is selected. The block decoder 212 controls the secondstage selectors 226, through which one memory block is selected out ofthe multitude of memory blocks which constitute the selected superblock. Accordingly, each word line, string select line and ground selectline of the selected memory block is connected to its global word line,string select line and ground select line through a series of two setsof pass devices, one which corresponds to first stage selector 224 andanother which corresponds to second stage selector 226.

Each super block has two sets of discharge devices connected to thestring select lines of the constituent memory blocks. Details of thesedischarge devices are shown in super block 200. A first set of dischargedevices 228 are connected to the string select lines of every memoryblock of super block 200. The discharge devices 228 are shown in thepresent example as n-channel transistors, which are connected to VSS.The gate terminals of all discharge devices 228 are connected to acommon discharge enable signal that is related to the super block signalcorresponding to super block 200. More specifically for the row decodingconfiguration example of FIG. 7, the common discharge enable signal isan inverted version of super block signal SB0, provided by inverter 230.A second set of discharge devices are connected to the same stringselect lines that the first discharge devices 228 are connected to. Inthe present embodiment, the second set of discharge devices includesn-channel transistors 232 and 234. Unlike discharge devices 228, eachdischarge device 232 and 234 is individually controlled by a localdischarge enable signal. For the present row decoding configurationexample of FIG. 7, each local discharge enable signal is related to ablock select signal provided by block decoder 212. Therefore dischargedevice 232 receives a local discharge enable signal that is an invertedversion of one block select signal, provided by inverter 236, anddischarge device 234 receives another local discharge enable signal thatis an inverted version of a second block select signal, provided byinverter 238.

It can thus be seen that unlike the block address decoder 58 of FIG. 3,the first decoding logic 100 of FIG. 7 does not decode the memory blockaddress down to the level of the individual memory blocks, but only downto the level of the super blocks. To illustrate the relationship betweensplit super block and memory block addressing, an example is nowdiscussed where it is assumed there are 2³ memory blocks per superblocks 200 to 202 of FIG. 7. If the memory block address provided to thememory device consists of s bits, then only s−3 most significant bits ofthe memory block address are decoded by first decoding logic 100, butnot the 3 least significant bits of the memory block address. The s−3most significant bits of the memory block address are referred to as thesuper block address. From this follows that each super block output (SB0to SBp) of the first decoding logic 100, and the respective super blockselection signals SBSL0 to SPSLp from the high voltage level shifters220 select one super block in its entirety, but not individual memoryblocks within this super block. Super block selection is achieved byactivating one first stage selector 224 of one select logic unit, suchas select logic unit 120 for example.

The 3 least significant bits of the memory block address not decoded byfirst decoding logic 100 are decoded by block decoder 212 to select onememory block out of all memory blocks in each super block. These 3 leastsignificant bits of the memory block address are referred to as a blockaddress. It is assumed that block decoder 212 is configured to providethe appropriate number of outputs based on a 2³ memory block selection.As for first decoding logic 100, one output of block decoder 212 isshifted to a high voltage level, such as through high voltage levelshifters 216 and 218 for example, in response to the decoding of these 3least significant bits of the memory block address. Then one selectorsub-set of second stage selector 226 corresponding to one memory blockin all select logic units 120 to 124 is activated. However, because onlyone first stage selector 224 of all select logic units 120 to 124 isactivated or enabled, only the memory block of the selected super blockreceives the global row signals GRS. In summary, the first stageselectors 224 function as a first demultiplexor for distributing GRS toone selected super block, and the second stage selector 226 of theselected super block functions as a second demultiplexor for furtherdistributing GRS from the first demultiplexor, to the selected memoryblock of the selected super block.

It is noted that for an unselected super block, the SSL lines forconnecting the NAND cell string to the bitline is held at VSS by adischarge devices 228. Each discharge device 228 is turned on wheneverthe corresponding super block is unselected, in order to decouple theNAND strings of all the constituent memory blocks from the bitlines.Hence, the discharge devices 228 are turned off for a selected superblock. For example, if a super block select signal is driven to anactive high logic level to select a particular super block, then thecorresponding discharge devices 228 of the super block are turned off.Otherwise, the super block select signal at an inactive low logic levelturns on the discharge devices 228. The second discharge devices 232 and234 are used to discharge SSL lines of unselected memory blocks of aselected super block to VSS. As previously discussed, a selected superblock will have one selected memory block. Therefore the remainingmemory blocks of the selected super block are unselected and their SSLlines are discharged to VSS.

For the purposes of simplifying the drawing of FIG. 7, the dischargedevices 228, 232 and 234 and inverter 230 are shown only for super block200, but would be included for the other super blocks in the memoryarray. In an optional configuration, the GSL lines can be dischargedusing two sets of discharge devices connected in the same way as shownfor discharge devices 228, 232 and 234. Alternately, just one set ofdischarge devices corresponding to discharge devices 228 or 232 and 234can be included.

FIG. 8 shows an alternate example of the split block decoding schemeembodiment of FIG. 6 where the pass circuit of the select logic unitsare simplified and the number of pass devices is reduced relative to theembodiment of FIG. 7. In the embodiment of FIG. 8, the first decodinglogic 100, the memory array super blocks 200, 202 and memory blocks 204,206 are the same as those shown in the embodiment of FIG. 7. The memoryblocks 204 and 206 can include a plurality of planar type NAND cellssuch as those shown in FIG. 3, or vertically stacked cells such as thevertical channel NAND cells of FIG. 4 or the vertically stacked NANDflash memory blocks with horizontal alignment of NAND cell strings ofFIG. 5. As is now described for FIG. 8, the configuration of seconddecoding logic 102 and select logic units 120 to 124 differs from thoseshown in FIG. 7.

Each of select logic units 120 to 124 includes a high voltage levelshifter 300 and a pass circuit 302, where details of one pass circuit302 is shown in select logic unit 120. In the embodiment of FIG. 8, passcircuit 302 includes a single stage selector including two sets of passdevices 304 and 306 shown as n-channel transistors. In the presentembodiment, each set of pass devices receives and provides a dedicatedset of global row signals to a corresponding memory block. As shown inFIG. 8, a first set of pass devices 304 provides a first set of globalrow signals GRS1 to memory block 204 and a second set of pass devices306 provides GRS a second set of global row signals GRS2 to memory block206. Each set of global row signals includes at least dedicated stringselect, wordline and ground select signals. In alternate configurationswhere each super block includes more than two memory blocks, the passcircuit 302 would include a corresponding number of sets of pass deviceselectrically coupled to each memory block, each receiving a dedicatedset of global row signals.

The high voltage level shifters 300 have the same function as thepreviously described high voltage level shifters 220 for the embodimentof FIG. 7. In otherwords, in response to a first row address RA_Aconsisting of higher order bits of the received memory block address,one of select logic units 120 to 124 is selected via super block signalsSB0 to SBp and super block select signals SBSL0 to SBSLp respectively.In the embodiment of FIG. 8, each super block select signal SBSL0 toSBSLp concurrently enables both pass device sets 304 and 306 of aselected select logic unit. Each of the sets of global row signals GRS1and GRS2 is provided by the second logic decoding logic 102.

The second decoding logic 102 includes an extended wordline addressdecoder 310 and multiple set wordline drivers 312, where the wordlinedrivers 312 receives different voltage levels, some of which are greaterthan the power supply voltage provided to the semiconductor memorydevice, to drive row signals with during read, program and eraseoperations. The extended wordline address decoder 310 differs from thewordline address decoder 210 of FIG. 7 in that it decodes, in additionto the wordline address information, the lower order bits of the memoryblock address not decoded by the first decoding logic 100. Therefore,the block addresses for memory blocks of each super block is integratedinto the decoding logic of extended wordline address decoder 310. In theexample of FIG. 8, the extended wordline address decoder 310 decodes thewordline address information and the lower order bits of the memoryblock address to provide dedicated sets of global row signals for eachmemory block of a super block. In otherwords, the second decoding logic102 of FIG. 8 outputs as many global word lines, string select lines andground select lines as there are local word lines, string select linesand ground select lines in the entirety of one super block. By example,the extended wordline address decoder 310 can include multipleidentically configured sets of wordline decoding logic, of which onlyone is activated in response to the lower order bits of the memory blockaddress.

For example, if each super block 200 to 202 consists of 8 blocks eachhaving NAND cell strings receiving 16 word lines, 1 string select lineand 1 ground select line, the total number of global row signal linesoutput by the second logic decoding logic 102 is 8×16=128 global wordlines, 8 global string select lines and 8 global ground select lines.Out of these sets of lines, only the set of lines corresponding to theselected block are activated, or driven to the required voltages for thespecific operation being executed. For ease of illustration, the exampleembodiment of FIG. 8 shows two memory blocks per super block, thereforethe second logic decoding logic 102 provides two dedicated sets ofglobal row signals GRS1 and GRS2. Each select logic unit receives allsets of the global row signals, therefore no additional decoding isneeded to select the correct memory block because only those global rowsignals activated by the extended wordline address decoder 310 and themultiple set wordline drivers 312 for the selected memory block aredriven. Accordingly, when a super block select line (SBSL0 to SBSLp) isactivated, the corresponding single stage selector 302 is enabled topass the active set of global row signals (GRS1 or GRS2) to thecorresponding memory block 204 or 206. Therefore the embodiment of FIG.8 does not require a separate block decoder, such as block decoder 212of FIG. 7, and a second stage of pass devices, such as second stageselector 226 of FIG. 7.

In the embodiment of FIG. 8, each super block has a set of dischargedevices connected to the string select lines of the constituent memoryblocks. Details of these discharge devices are shown in super block 200.The discharge devices 314 are connected to the string select lines ofevery memory block of super block 200. The discharge devices 314 areshown in the present example as n-channel transistors, which areconnected to VSS. The gate terminals of all discharge devices 314 areconnected to a common discharge enable signal that is related to thesuper block signal corresponding to super block 200. More specificallyfor the row decoding configuration example of FIG. 8, the commondischarge enable signal is an inverted version of super block signalSB0, provided by inverter 316.

For an unselected super block, the SSL lines for connecting the NANDcell string to the bitline is held at VSS by a discharge devices 314.Each discharge device 314 is turned on whenever the corresponding superblock is unselected, in order to decouple the NAND strings of all theconstituent memory blocks from the bitlines. Hence, the dischargedevices 314 are turned off for a selected super block. For example, if asuper block select signal is driven to an active high logic level toselect a particular super block, then the corresponding dischargedevices 314 of the super block are turned off. Otherwise, the superblock select signal at an inactive low logic level turns on thedischarge devices 314.

For the purposes of simplifying the drawing of FIG. 8, the dischargedevices 314 and inverter 316 are shown only for super block 200, butwould be included for the other super blocks in the memory array. In anoptional configuration, the GSL lines can be discharged using a set ofdischarge devices connected in the same way as shown for dischargedevices 314.

FIG. 9 is an alternate example of the split block decoding schemeembodiment of FIG. 8, in which a different configuration of the seconddecoding logic 102 is presented. Many features previously shown in FIG.8 appear in FIG. 9 annotated with the same reference numbers. The seconddecoding logic 102 includes a wordline address decoder 350, a wordlinedriver circuit 352, a block decoder 354, and a selector circuitincluding a first set of pass transistors 356 and a second set of passtransistors 358. The wordline address decoder 350 and the wordlinedriver circuit 352 function the same as corresponding circuits 210 and214 respectively of the embodiment of FIG. 7, and provides a single setof master global row signals MGRS in response to received wordlineaddress information. The master global row signals MGRS include globalword lines, a string select line and a ground select line.

The master global row signals MGRS are received by the pass transistors356 and 358, which selectively pass MGRS as either global row signalsGRS1 or GRS2 in response to block select signals provided by blockdecoder 354. It is noted that each of pass transistors 356 and 358represents a group of pass transistors for passing each of the masterglobal row signals MGRS in response to the same block select signal.Accordingly, a memory block of a super block is selected when thecorresponding GRS1 or GRS2 lines are electrically connected to MGRS. Inconfigurations where there is more than two memory blocks per superblock, there will be the same number of pass transistors for providingglobal row signals to each memory block. Both the wordline addressinformation and block address information are provided in the second rowaddress RA_B, where the super block address and block addressinformation are parsed from the received memory block address portion ofthe row address received by the memory device.

Each super block has two sets of discharge devices connected to thestring select lines of the constituent memory blocks. Details of thesedischarge devices are shown in super block 200. In addition to a firstset of discharge devices 360 which are configured and operate similarlyto discharge devices 228 previously shown in the embodiment of FIG. 7,the embodiment of FIG. 9 includes a second set of discharge devicesconnected to the same string select lines that the first dischargedevices 360 are connected to. In the present embodiment, the second setof discharge devices includes n-channel transistors 362 and 364. Unlikedischarge devices 360, each discharge device 362 and 364 is individuallycontrolled by a local discharge enable signal. For the present rowdecoding configuration example of FIG. 9, each local discharge enablesignal is related to a block select signal provided by block decoder354. Therefore discharge device 362 receives a local discharge enablesignal that is an inverted version of one block select signal, providedby inverter 366, and discharge device 364 receives another localdischarge enable signal that is an inverted version of a second blockselect signal, provided by inverter 368.

The operation of the first and second sets of discharge devices issimilar to the first and second sets of discharge devices shown in theembodiment of FIG. 7. Each discharge device 360 is turned on wheneverthe corresponding super block is unselected, in order to decouple theNAND strings of all the constituent memory blocks from the bitlines.Hence, the discharge devices 360 are turned off for a selected superblock. For example, if a super block select signal is driven to anactive high logic level to select a particular super block, then thecorresponding discharge devices 360 of the super block are turned off.Otherwise, the super block select signal at an inactive low logic levelturns on the discharge devices 360. The second discharge devices 362 and364 are used to discharge SSL lines of unselected memory blocks of aselected super block to VSS. As previously discussed, a selected superblock will have one selected memory block. Therefore the remainingmemory blocks of the selected super block are unselected and their SSLlines are discharged to VSS. For the purposes of simplifying the drawingof FIG. 9, the discharge devices 360, 362 and 364 are shown only forsuper block 200, but would be included for the other super blocks in thememory array. In an optional configuration, the GSL lines can bedischarged using two sets of discharge devices connected in the same wayas shown for discharge devices 360, 362 and 364. Alternately, just oneset of discharge devices corresponding to discharge devices 360 or 362and 364 can be included.

The embodiment of FIG. 6 shows an arrangement of the row circuits 120 to124 of the select block 104 formed on one side of the memory array.According to an alternate embodiment, the row circuits 120 to 124 of theselect block 104 can be arranged on both sides of the memory array. FIG.10 shows such an alternate arrangement of the row circuits, according tothe present alternate embodiment.

In FIG. 10, the memory array includes the same super blocks 110 and 112to 114 as those previously shown in the embodiment of FIG. 6. Formed onone side of the super blocks is a first portion of a first decoder logic400 and a first portion of select logic units, of which only selectlogic unit 402 is shown in FIG. 10. Formed on an opposite side of thesuper blocks is a second portion of a first decoder logic 404 and asecond portion of select logic units, of which only select logic units406 and 408 are shown in FIG. 10. In this example, it is assumed thatselect logic unit 406 is a first select logic unit, select logic unit408 is a last select logic unit, and select logic unit 402 is a secondand intermediate select logic unit.

It should be noted that select logic units 402, 406 and 408 are formedadjacent to the super blocks they provide row signals to, and startingwith the first select logic unit 406, every second select logic unit isformed on an opposite side of the super blocks. This can be referred toas an interleaved row circuit arrangement. Formed outside of a row pitchlimited area between the super blocks and the first portion of the firstdecoder logic 400, and the super blocks and the second portion of thesecond decoder logic 404, is a first portion of second decoding logic410 and a second portion of second decoding logic 412. The decoder logicblocks 410 and 412 are shown on either side of the super blocks, butthey can be formed underneath or above the memory array of super blocks.In the presently shown example, the decoder logic blocks 410 and 412 areconfigured identically to each other.

Together, the first portion of the first decoder logic 400 and thesecond portion of the first decoder logic 404 have the same function asfirst decoder logic 100 of FIG. 6, except that both portions 400 and 404are physically subdivided into 2 separate parts. In the presently shownexample, the right side select logic units including select logic units406 and 408 can be considered even numbered select logic units, whilethe left side select logic units including select logic unit 402 can beconsidered odd numbered select logic units. Therefore the first portionof the first decoder logic 400 receives a first portion of the first rowaddress RA_A_odd for selecting just the odd numbered select logic units,and the second portion of the second decoder logic 404 receives a secondportion of the first row address RA_A_even for selecting just the evennumbered select logic units. The first portion of the second decodinglogic 410 and the second portion of the second decoding logic 412 bothreceive a second portion of the row address RA_B.

In one example implementation of the embodiment of FIG. 10, the selectlogic units 402, 406 and 408 can have the same configuration of selectlogic unit 120 shown in FIG. 7, and the decoder logic blocks 410 and 412can each have the same configuration of second decoder logic 102 shownin FIG. 7. In this example, the global row signals provided by seconddecoder logic block 410 are identical to the global row signals providedby second decoder logic block 412 for selecting the same memory blockposition in each super block. Therefore the decoder logic blocks 410 and412 are identically configured to each other.

In another example implementation of the embodiment of FIG. 10, theselect logic units 402, 406 and 408 can have the same configuration ofselect logic unit 120 shown in FIG. 8, and the decoder logic blocks 410and 412 can each have the same configuration of second decoder logic 102shown in FIG. 8. In this example, each of second decoder logic blocks410 and 412 are identically configured to each other. Thus both seconddecoder logic blocks 410 and 412 provides multiple sets of global rowsignals, one set for each memory block of a super block, where one setis driven to appropriate voltage levels based on the second row addressRA_B for accessing the same memory block position in each super block.

In the embodiment of FIG. 10, it is not necessary to have two physicallydivided second decoder logic circuits. In an alternate embodiment, bothcan be formed as a single second decoder logic circuit as shown in theexamples of FIGS. 7 and 8 and the sets of global row signals are routedto both sides of the super blocks.

The advantage provided by the embodiment of FIG. 10 is that the rowpitch spacing of the select logic units on one side of the super blockscan be greater than the row pitch spacing of a super block. Inotherwords, each select logic unit on one side of the super blocks canextend into the row pitch area of an adjacent super block. Thissituation may occur if the number of memory blocks 116 per super blockis small. For example, if the memory blocks 116 consist of verticalchannel NAND cell strings, then a reduction in the number of blocks persuper block will reduce the row pitch of a super block. However, it maynot be possible to correspondingly reduce the row pitch of the selectlogic unit. For memory blocks consisting of planar type NAND cellstrings, a reduction in the number of memory cells per string may resultin the same problem, which can be resolved by the embodiment of FIG. 10.

The embodiments of the disclosure shown in FIGS. 6 to 10 can be appliedto memory arrays having memory blocks consisting of planar type NANDcell strings formed on a single plane, or vertically stacked NAND flashmemory blocks with horizontal alignment of NAND cell strings, or memoryblocks consisting of vertical channel NAND cell strings.

In the preceding description, for purposes of explanation, numerousdetails are set forth in order to provide a thorough understanding ofthe embodiments. However, it will be apparent to one skilled in the artthat these specific details are not required. In other instances,well-known electrical structures and circuits are shown in block diagramform in order not to obscure the understanding. For example, specificdetails are not provided as to whether the embodiments described hereinare implemented as a software routine, hardware circuit, firmware, or acombination thereof.

Embodiments of the disclosure can be represented as a computer programproduct stored in a machine-readable medium (also referred to as acomputer-readable medium, a processor-readable medium, or a computerusable medium having a computer-readable program code embodied therein).The machine-readable medium can be any suitable tangible, non-transitorymedium, including magnetic, optical, or electrical storage mediumincluding a diskette, compact disk read only memory (CD-ROM), memorydevice (volatile or non-volatile), or similar storage mechanism. Themachine-readable medium can contain various sets of instructions, codesequences, configuration information, or other data, which, whenexecuted, cause a processor to perform steps in a method according to anembodiment of the disclosure. Those of ordinary skill in the art willappreciate that other instructions and operations necessary to implementthe described implementations can also be stored on the machine-readablemedium. The instructions stored on the machine-readable medium can beexecuted by a processor or other suitable processing device, and caninterface with circuitry to perform the described tasks.

The above-described embodiments are intended to be examples only.Alterations, modifications and variations can be effected to theparticular embodiments by those of skill in the art without departingfrom the scope, which is defined solely by the claims appended hereto.

What is claimed is:
 1. A method for operating a non-volatile memorydevice having a memory array, wherein the memory array includes aplurality of memory blocks organized as groups of memory blocks, themethod comprising: selecting, by row decoding circuitry, a group of theplurality of memory blocks in response to a first row address;selecting, by the row decoding circuitry, a memory block of the groupfor receiving row signals in response to a second row address; andproviding, by first decoder logic of the row decoding circuitry, a superblock signal corresponding to each group of the plurality of memoryblocks in response to the first row address.
 2. The method of claim 1,wherein the row signals includes string select signals corresponding toeach memory block of the group, the method further comprising coupling,by discharge devices of the non-volatile memory device, each of thestring select signals to ground in response to the group beingunselected.
 3. The method of claim 2, further comprising controllingeach of the discharge devices by logic states of the super block signal.4. The method of claim 2, wherein the row signals includes ground selectsignals corresponding to each memory block of the group, the methodfurther comprising coupling, by ground select discharge devices of thenon-volatile memory device, each of the ground select signals to groundin response to the group being unselected.
 5. The method of claim 4,further comprising controlling each of the ground select dischargedevices by logic states of the super block signal.
 6. The method ofclaim 2, further comprising selecting, by a select logic unit of the rowdecoding circuitry, the group addressed by the first row address and thememory block of the group addressed by the second row address.
 7. Themethod of claim 6, wherein the first row address includes higher orderbits of a memory block address.
 8. The method of claim 7, furthercomprising providing, by second decoder logic of the row decodingcircuitry, block signals corresponding to each memory block of the groupin response to the second row address.
 9. The method of claim 8, whereinthe block signals include block select signals corresponding to eachmemory block of the group, and row signals for accessing memory cells ofeach memory block of the group.
 10. The method of claim 8, wherein theblock signals include dedicated sets of row signals corresponding toeach memory block of the group.
 11. A system comprising a plurality ofnon-volatile memory devices, each of the memory devices comprising: amemory array including a plurality of memory blocks organized as groupsof memory blocks; and row decoding circuitry configured to select agroup of the plurality of memory blocks in response to a first rowaddress and to select a memory block of the group for receiving rowsignals in response to a second row address; wherein the row decodingcircuitry includes first decoder logic configured to provide a superblock signal corresponding to each group of the plurality of memoryblocks in response to the first row address.
 12. The system of claim 11,further including high voltage level shifters for voltage level shiftingthe super block signals.
 13. The system of claim 11, wherein the rowsignals includes string select signals corresponding to each memoryblock of the group, the non-volatile memory device further includingdischarge devices for coupling each of the string select signals toground when the group is unselected.
 14. The system of claim 13, whereineach of the discharge devices is controlled by logic states of the superblock signal.
 15. The system of claim 13, wherein the row signalsincludes ground select signals corresponding to each memory block of thegroup, the non-volatile memory device further including ground selectdischarge devices for coupling each of the ground select signals toground when the group is unselected.
 16. The system of claim 13, whereinthe row decoding circuitry includes a select logic unit configured toselect the group addressed by the first row address and the memory blockof the group addressed by the second row address.
 17. The system ofclaim 16, wherein the select logic unit is formed within a row pitch ofthe group.
 18. The system of claim 16, wherein the first decoder logicand the select logic unit are formed on one side of the memory array.19. The system of claim 16, wherein the first row address includeshigher order bits of a memory block address, and wherein the rowdecoding circuitry includes second decoder logic configured to provideblock signals corresponding to each memory block of the group inresponse to the second row address.
 20. The system of claim 19, whereinthe first decoder logic includes a first portion formed on one side ofthe memory array and a second portion formed on an opposite side of thememory array.